Liu Q et al. (2011) J Physiol "Muscle memory."

Jorgensen E, Liu Q

[J Physiol, 2011]

Liu Q et al. (2010) Science "Molecular biology. Dicer's cut and switch."

Paroo Z, Liu Q

[Science, 2010]

Liu J et al. (2014) Curr Biol "Aging: the blurry line between life and death."

Liu J, Finkel T

[Curr Biol, 2014]

Although historically reactive oxygen species have been implicated as apotential cause of ageing, recent evidence suggests that a modest increase inoxidants can actually extend lifespan. A new study suggests that, in Caenorhabditis elegans, reactive oxygen species regulate longevity through apathway classically linked to apoptosis.

Kirkwood TB (2013) Cell Metab "Untangling functional declines in the locomotion of aging worms."

Kirkwood TB

[Cell Metab, 2013]

All physiological functions decline with age, but which changes are primary and which are secondary is not always clear. Liu et al. (2013), examining functional changes in the muscles and motor neurons of C. elegans, suggest that when it comes to locomotion, it is the nervous system that shows earlier age-related deterioration.

Skora S et al. (2013) EMBO J "Life(span) in balance: oxygen fuels a sophisticated neural network for lifespan homeostasis in C. elegans."

Zimmer M, Skora S

[EMBO J, 2013]

A key finding of modern ageing research is that our limitation in lifespan is more than the result of accumulated organismal decay. Lifespan is regulated by genetically defined chemosensory and endocrine pathways, which integrate signals that reflect the internal and external status of the animal. New findings by Liu and Cai unravel a role for the environmental gases oxygen and carbon dioxide in the regulation of lifespan homeostasis and thus a novel function of oxygen-chemosensory neurons in C. elegans.

Tuck S (2011) Curr Biol "Extracellular vesicles: budding regulated by a phosphatidylethanolamine translocase."

Tuck S

[Curr Biol, 2011]

Recent work on a Caenorhabditis elegans transmembrane ATPase reveals a central role for the aminophospholipid phosphatidylethanolamine in the production of a class of extracellular vesicles.

Kress E et al. (2011) Nat Cell Biol "Aurora A in cell division: kinase activity not required."

Kress E, Gotta M

[Nat Cell Biol, 2011]

Aurora A kinase is a key regulator of cell division, whose functions were attributed to its ability to phosphorylate diverse substrates. Aurora A is now shown to have a kinase-independent role in the regulation of chromatin-mediated microtubule assembly.

Musacchio A (2015) Elife "Closing the Mad2 cycle."

Musacchio A

[Elife, 2015]

Chromosome separation is regulated by a cycle that involves a protein undergoing an unusual topological conversion.

Prosser SL et al. (2015) Curr Biol "Centrosome biology: the ins and outs of centrosome assembly."

Pelletier L, Prosser SL

[Curr Biol, 2015]

As a microtubule-organizing center, the centrosome undergoes a dramatic increase in size - via expansion of the pericentriolar material - during mitosis. Recent work reveals shared assembly properties of a protein scaffold that facilitates and supports this expansion, a process critical to spindle assembly.

Louis T et al. (2014) Cell "Neurons and behavior: ex uno, plures."

Louis T, Tomchik SM

[Cell, 2014]

Li et al. demonstrate that a single interneuron can regulate analog- and digital-like behaviors guided by two different postsynaptic neurons. Releasing a single neurotransmitter onto downstream neurons that express receptors with distinct biophysical properties enables a small set of neurons to direct a range of functional responses.